1. Introduction

Part I Classical Transport

2. Phase-Lag Models

2.1 Maxwell-Cattaneo-Vernotte Equation

2.2. Dual-Phase-Lag Model

2.2.1. Nonlocal Dual-Phase-Lag Model

2.3.Triple-Phase-Lag Model

2.3.1. Nonlocal Triple-Phase-Lag Model

3. Phonon Models

3.1. Guyer-Krumhansl (GK) Equation

3.2. Ballistic-Diffusive Model

3.3. Unified Nondiffusive-Diffusive Model

3.4. Two-fluid model

3.5. Generalized Fourier Law by Hua et al.

3.6. Phonon hydrodynamics

3.7. Relaxon Model

4. Thermomass Model

4.1. Equation of State (EOS) of the Thermon Gas

4.1.1. EOS of thermon gas in ideal gas

4.1.2. EOS of thermon gas in dielectrics

4.1.3. EOS of thermon gas in metals

4.2. Equations of Motion of Thermon Gas

4.3. Heat flow Choking Phenomenon

4.4. Dispersion of Thermal Waves

5. Mesoscopic Moment Equations

Thermodynamic Models

6.1. Jou & Cimmelli Model

6.2. Kov\'acs & V\'an Model

6.3. Rogolino et al. Models

7.  Fractional Models

7.1. Fractional Fourier Model

7.1.1. Nonlinear Diffusivity

7.1.2. Fractional Pennes model

7.2. Zingales's Fractional Order Model

7.3. Fractional Cattaneo and SPL Models

7.4. Fractional DPL Model

7.5. Fractional TPL Model

7.5.1. Nonlocal Fractional TPL Model

8. Fractional Boltzmann and Fokker-Planck equations

8.1. Continuous Time Random Walks

 8.1.1. L\'evy (Khintchine-L\'evy) walks

8.2. Kramers-Fokker-Plank equation

9. Elasticity and thermal expansion coupling

9.1. Non-Fourier Thermoelasticity

9.1.1. Fractional Thermoelasticity

10. Some Exact Solutions

10.1. Phase-Lag Models

10.2. Phonon Models

10.3. Fractional Models

Part II Relativistic Transport

*** 1

*** 2

Part  III Quantum Transport

13. Landauer approach

14. Green-Kubo approach

15. Phonon Coherent Transport

16. Conclusions

17.1. Fractional Derivatives

 17.1.1. Riemann-Liouville Fractional Integral

 17.1.2. Riemann-Liouville Fractional Derivative

17.1.2.1. Leibniz' formula

17.1.2.2. Fa\'a di Bruno formula (chain rule)

17.1.2.3. Fractional Taylor expansion

17.1.2.4. Symmetrised space derivative

 1 7.1.3. Caputo Fractional Derivative

 17.1.4. Caputo & Fabrizio Fractional Derivatives

 17.1.5. GC & GRL derivatives

17.1.5.1. GC derivatives

17.1.5.2. GRL derivatives

 17.1.7. Gr\"unwald - Letnikov Derivative

 17.1.8. Riesz Fractional Operators

 17.1.9. Weyl Fractional Derivative

 17.1.10. Erd\'elye-Kober Fractional Operators

 17.1.11. Interpretation of Fractional Integral and Derivatives

 17.1.12. Local Fractional Derivatives

17.1.12.1. "Conformable" Fractional Derivative

17.2. Fractional Differential Equations

 17.2.1. Distributed order differential equations

 17.2.2 Special Functions

17.2.2.1. Mittag-Leffler Functions

17.2.2.3. Wright Functions

17.3. Solution of Fractional Differential Equations

 17.3.1. Analytic Methods

 17.3.2. Numerical Methods

Alexander Zhmakin was born on December 3rd, 1951 in Leningrad, USSR. He completed his education at the Leningrad Polytechnical Institute, graduating in 1974. In 1980, he obtained his PhD in the field of numerical simulation of nonequilibrium shocked flows. He later received his Dr.Sci. in 1992, for his work on the numerical simulation of gas phase and liquid phase epitaxy. Zhmakin's main interests include computational fluid dynamics and heat transfer, as well as the simulation of single crystal growth and cryobiology.

This book presents a broad and well-structured overview of various non-Fourier heat conduction models. The classical Fourier heat conduction model is valid for most macroscopic problems. However, it fails when the wave nature of the heat propagation becomes dominant and memory or non-local spatial effects become significant; e.g., during ultrafast heating, heat transfer at the nanoscale, in granular and porous materials, at extremely high values of the heat flux, or in heat transfer in biological tissues. The book looks at numerous non-Fourier heat conduction models that incorporate time non-locality for materials with memory, such as hereditary materials, including fractional hereditary materials, and/or spatial non-locality, i.e. materials with a non-homogeneous inner structure. Beginning with an introduction to classical transport theory, including phase-lag, phonon, and thermomass models, the book then looks at various aspects of relativistic and quantum transport, including approaches based on the Landauer formalism as well as the Green-Kubo theory of linear response. Featuring an appendix that provides an introduction to methods in fractional calculus, this book is a valuable resource for any researcher interested in theoretical and numerical aspects of complex, non-trivial heat conduction problems.